Hypovolemia Explained

Hypovolemia
Synonyms:Oligemia, hypovolaemia, oligaemia, hypovolæmia, volume depletion
Field:Emergency medicine
Symptoms:Headache, fatigue, nausea, profuse sweating, dizziness
Complications:Hypovolemic shock
Differential:Dehydration

Hypovolemia, also known as volume depletion or volume contraction, is a state of abnormally low extracellular fluid in the body.[1] This may be due to either a loss of both salt and water or a decrease in blood volume.[2] [3] Hypovolemia refers to the loss of extracellular fluid and should not be confused with dehydration.[4]

Hypovolemia is caused by a variety of events, but these can be simplified into two categories: those that are associated with kidney function and those that are not.[5] The signs and symptoms of hypovolemia worsen as the amount of fluid lost increases.[6] Immediately or shortly after mild fluid loss (from blood donation, diarrhea, vomiting, bleeding from trauma, etc.), one may experience headache, fatigue, weakness, dizziness, or thirst. Untreated hypovolemia or excessive and rapid losses of volume may lead to hypovolemic shock.[7] Signs and symptoms of hypovolemic shock include increased heart rate, low blood pressure, pale or cold skin, and altered mental status. When these signs are seen, immediate action should be taken to restore the lost volume.

Signs and symptoms

Signs and symptoms of hypovolemia progress with increased loss of fluid volume.

Early symptoms of hypovolemia include headache, fatigue, weakness, thirst, and dizziness. The more severe signs and symptoms are often associated with hypovolemic shock. These include oliguria, cyanosis, abdominal and chest pain, hypotension, tachycardia, cold hands and feet, and progressively altering mental status.

Causes

The causes of hypovolemia can be characterized into two categories:

Kidney

Other

Pathophysiology

The signs and symptoms of hypovolemia are primarily due to the consequences of decreased circulating volume and a subsequent reduction in the amount of blood reaching the tissues of the body. In order to properly perform their functions, tissues require the oxygen transported in the blood.[9] A decrease in circulating volume can lead to a decrease in bloodflow to the brain, resulting in headache and dizziness.

Baroreceptors in the body (primarily those located in the carotid sinuses and aortic arch) sense the reduction of circulating fluid and send signals to the brain to increase sympathetic response (see also: baroreflex).[10] This sympathetic response is to release epinephrine and norepinephrine, which results in peripheral vasoconstriction (reducing size of blood vessels) in order to conserve the circulating fluids for organs vital to survival (i.e. brain and heart). Peripheral vasoconstriction accounts for the cold extremities (hands and feet), increased heart rate, increased cardiac output (and associated chest pain). Eventually, there will be less perfusion to the kidneys, resulting in decreased urine output.

Diagnosis

Hypovolemia can be recognized by a fast heart rate, low blood pressure,[11] and the absence of perfusion as assessed by skin signs (skin turning pale) and/or capillary refill on forehead, lips and nail beds. The patient may feel dizzy, faint, nauseated, or very thirsty. These signs are also characteristic of most types of shock.[12]

In children, compensation can result in an artificially high blood pressure despite hypovolemia (a decrease in blood volume). Children typically are able to compensate (maintain blood pressure despite hypovolemia) for a longer period than adults, but deteriorate rapidly and severely once they are unable to compensate (decompensate).[13] Consequently, any possibility of internal bleeding in children should be treated aggressively.[14]

Signs of external bleeding should be assessed, noting that individuals can bleed internally without external blood loss or otherwise apparent signs.[15]

There should be considered possible mechanisms of injury that may have caused internal bleeding, such as ruptured or bruised internal organs. If trained to do so and if the situation permits, there should be conducted a secondary survey and checked the chest and abdomen for pain, deformity, guarding, discoloration or swelling. Bleeding into the abdominal cavity can cause the classical bruising patterns of Grey Turner's sign (bruising along the sides) or Cullen's sign (around the navel).[16]

Investigation

In a hospital, physicians respond to a case of hypovolemic shock by conducting these investigations:

Stages

Untreated hypovolemia can lead to shock (see also: hypovolemic shock). Most sources state that there are 4 stages of hypovolemia and subsequent shock;[17] however, a number of other systems exist with as many as 6 stages.[18]

The 4 stages are sometimes known as the "Tennis" staging of hypovolemic shock, as the stages of blood loss (under 15% of volume, 15–30% of volume, 30–40% of volume and above 40% of volume) mimic the scores in a game of tennis: 15, 15–30, 30–40 and 40.[19] It is basically the same as used in classifying bleeding by blood loss.

The signs and symptoms of the major stages of hypovolemic shock include:[20] [21]

Stage 1Stage 2Stage 3Stage 4
Blood loss Up to 15% (750 mL) 15–30% (750–1500 mL) 30–40% (1500–2000 mL) Over 40% (over 2000 mL)
Blood pressure Normal (Maintained
by vasoconstriction)
Systolic BP < 100 Systolic BP < 70
Heart rate Normal Slight tachycardia (> 100 bpm) Tachycardia (> 120 bpm) Extreme tachycardia (> 140 bpm) with weak pulse
Respiratory rate Normal Increased (> 20) Tachypneic (> 30) Extreme tachypnea
Mental status Normal Slight anxiety, restless Altered, confused Decreased LOC, lethargy, coma
Skin Pale, cool, clammy Extreme diaphoresis; mottling possible
Capillary refill Normal Delayed Delayed Absent
Urine output Normal 20–30 mL/h 20 mL/h Negligible

Treatment

Field care

The most important step in treatment of hypovolemic shock is to identify and control the source of bleeding.[22]

Medical personnel should immediately supply emergency oxygen to increase efficiency of the patient's remaining blood supply. This intervention can be life-saving.[23]

Also, the respiratory pump is especially important during hypovolemia as spontaneous breathing may help reduce the effect of this loss of blood pressure on stroke volume by increasing venous return.[24]

The use of intravenous fluids (IVs) may help compensate for lost fluid volume, but IV fluids cannot carry oxygen the way blood does—however, researchers are developing blood substitutes that can. Infusing colloid or crystalloid IV fluids also dilutes clotting factors in the blood, increasing the risk of bleeding. Current best practice allow permissive hypotension in patients with hypovolemic shock,[25] both avoid overly diluting clotting factors and avoid artificially raising blood pressure to a point where it "blows off" clots that have formed.[26] [27]

Hospital treatment

Fluid replacement is beneficial in hypovolemia of stage 2, and is necessary in stage 3 and 4. See also the discussion of shock and the importance of treating reversible shock while it can still be countered.

The following interventions are carried out:

Vasopressors (such as dopamine and noradrenaline) should generally be avoided, as they may result in further tissue ischemia and don't correct the primary problem. Fluids are the preferred choice of therapy.[28]

History

In cases where loss of blood volume is clearly attributable to bleeding (as opposed to, e.g., dehydration), most medical practitioners prefer the term exsanguination for its greater specificity and descriptiveness, with the effect that the latter term is now more common in the relevant context.[29]

See also

Notes and References

  1. Book: McGee, Steven . Evidence-based physical diagnosis . Elsevier . 2018 . 978-0-323-39276-1 . Philadelphia, PA . 959371826 . The term hypovolemia refers collectively to two distinct disorders: (1) volume depletion, which describes the loss of sodium from the extracellular space (i.e., intravascular and interstitial fluid) that occurs during gastrointestinal hemorrhage, vomiting, diarrhea, and diuresis; and (2) dehydration, which refers to the loss of intracellular water (and total body water) that ultimately causes cellular desiccation and elevates the plasma sodium concentration and osmolality. . vanc.
  2. Web site: Hypovolemia definition – MedicineNet . Medterms.com . 2012-03-19 . 2015-11-01 . 2014-01-23 . https://web.archive.org/web/20140123013022/http://www.medterms.com/script/main/art.asp?articlekey=3871 . dead .
  3. Web site: Hypovolemia | definition of hypovolemia by Medical dictionary . Medical-dictionary.thefreedictionary.com . 2015-11-01.
  4. Bhave G, Neilson EG . August 2011 . Volume depletion versus dehydration: how understanding the difference can guide therapy . American Journal of Kidney Diseases . 58 . 2 . 302–09 . 10.1053/j.ajkd.2011.02.395 . 4096820 . 21705120.
  5. Book: Harrison's principles of internal medicine. Jameson. J. Larry. Kasper. Dennis L.. Longo. Dan L.. Fauci. Anthony S.. Hauser. Stephen L.. Loscalzo. Joseph. 9781259644030. 20th. New York. McGraw-Hill Education. 1029074059. 2018.
  6. Web site: Hypovolemic shock: MedlinePlus Medical Encyclopedia. medlineplus.gov. en. 2019-09-02.
  7. Kolecki. Paul. vanc . October 13, 2016. Hypovolemic Shock. Medscape.
  8. Danic B, Gouézec H, Bigant E, Thomas T . [Incidents of blood donation] . fr . Transfusion Clinique et Biologique . 12 . 2 . 153–59 . June 2005 . 15894504 . 10.1016/j.tracli.2005.04.003 .
  9. Carreau A, El Hafny-Rahbi B, Matejuk A, Grillon C, Kieda C . June 2011 . Why is the partial oxygen pressure of human tissues a crucial parameter? Small molecules and hypoxia . Journal of Cellular and Molecular Medicine . 15 . 6 . 1239–53 . 10.1111/j.1582-4934.2011.01258.x . 4373326 . 21251211.
  10. Book: StatPearls . Armstrong M, Moore RA . 2019 . StatPearls Publishing . Physiology, Baroreceptors . 30844199 . 2019-09-02 . http://www.ncbi.nlm.nih.gov/books/NBK538172/.
  11. Web site: Stage 3: Compensated Shock. https://web.archive.org/web/20100611035541/http://www.stagesofshock.com/stage3/index.html . 2010-06-11.
  12. Book: Alpert . Joseph S. . Manual of Cardiovascular Diagnosis and Therapy . Ewy . Gordon A. . Lippincott Williams & Wilkins . 2002 . 978-0-7817-2803-4 . 101 . vanc.
  13. Book: Henry . Mark C . EMT Prehospital Care . Stapleton . Edward R . Edgerly . Dennis . Jones & Bartlett Publishers . 2011 . 978-0-323-08533-5 . 471– . vanc.
  14. Book: Assuma Beevi. Pediatric Nursing Care Plans. 2012. JP Medical Ltd. 978-93-5025-868-2. 47–.
  15. Book: Clement I . Textbook on First Aid and Emergency Nursing. 2013. Jaypee Brothers Publishers. 978-93-5025-987-0. 113–.
  16. Book: Blaber . Amanda . Assessment Skills For Paramedics . Harris . Graham . McGraw-Hill Education . 2011 . 978-0-335-24199-6 . 83– . vanc.
  17. Web site: Hudson, Kristi. Hypovolemic Shock – 1 Nursing CE. https://web.archive.org/web/20090606044910/http://dynamicnursingeducation.com/class.php?class_id=47&pid=18 . 2009-06-06.
  18. Web site: Stage 1: Anticipation stage (a new paradigm). https://web.archive.org/web/20100116055045/http://www.stagesofshock.com/stage1/index.html. 2010-01-16.
  19. Book: Greaves. Ian. Porter. Keith. Hodgetts. Timothy. 3 . Woollard. Malcolm. vanc . Emergency Care: A Textbook for Paramedics. 2006. Elsevier Health Sciences. 9780702025860. 229.
  20. Book: Agabegi . Elizabeth D . Step-Up to Medicine (Step-Up Series) . Steven S. . Agabegi . Lippincott Williams & Wilkins . 2008 . 978-0-7817-7153-5 . Hagerstwon, MD . registration . vanc.
  21. Book: Robbins and Cotran pathologic basis of disease. Kumar. Vinay. Abbas. Abul K.. Aster. Jon C.. Illustrated by Perkins, James A.. 2015. 9781455726134. 9th. Philadelphia, PA. Saunders. 879416939.
  22. Bulger . E. M. . Snyder . D. . Schoelles . K. . Gotschall . C. . Dawson . D. . Lang . E. . White . L. . 15742568 . 1 . 2014 . An evidence-based prehospital guideline for external hemorrhage control: American College of Surgeons Committee on Trauma . Prehospital Emergency Care . 18 . 2 . 163–173 . 10.3109/10903127.2014.896962 . 24641269 .
  23. Takasu . A. . Prueckner . S. . Tisherman . S. A. . Stezoski . S. W. . Stezoski . J. . Safar . P. . 2000 . Effects of increased oxygen breathing in a volume controlled hemorrhagic shock outcome model in rats . Resuscitation . 45 . 3 . 209–220 . 10959021 . 10.1016/s0300-9572(00)00183-0 .
  24. Skytioti M, Søvik S, Elstad M . Respiratory pump maintains cardiac stroke volume during hypovolemia in young, healthy volunteers . J Appl Physiol . 124 . 5 . 1319–1325 . May 2018 . 29494288 . 10.1152/japplphysiol.01009.2017 . 3626450 . 10852/72205 . free .
  25. Web site: Permissive Hypotension . Trauma.Org . 1997-08-31 . 2015-11-01 . https://web.archive.org/web/20131127011402/http://www.trauma.org/archive/resus/permissivehypotension.html . 2013-11-27 . dead .
  26. Book: Kennamer . Mike . Intravenous Therapy for Prehospital Providers . American Academy of Orthopaedic Surgeons (AAOS) . Jones & Bartlett Publishers . 2013 . 978-1-4496-4204-4 . 63– . vanc.
  27. Book: de Franchis . Roberto . Variceal Hemorrhage . Dell'Era . Alessandra . Springer Science & Business Media . 2014 . 978-1-4939-0002-2 . 113– . vanc.
  28. Failure of dobutamine to improve liver oxygenation during resuscitation with a crystalloid solution after experimental haemorrhagic shock. The European Journal of Surgery = Acta Chirurgica. 162. 12. 973–979. Pubmed-NCBI . 1996-08-31 . 2017-11-21. Nordin. A. J.. Mäkisalo. H.. Höckerstedt. K. A.. 9001880 .
  29. Geeraedts LM, Kaasjager HA, van Vugt AB, Frölke JP . January 2009 . Exsanguination in trauma: A review of diagnostics and treatment options . Injury . 40 . 1 . 11–20 . 10.1016/j.injury.2008.10.007 . 19135193.